Molecular genetics and genomics of the Rosoideae: state of the art and future perspectives

REVIEW ARTICLE

Molecular genetics and genomics of the Rosoideae: state of the

art and future perspectives

Sara Longhi1, Lara Giongo1, Matteo Buti1, Nada Surbanovski1, Roberto Viola1, Riccardo Velasco1, Judson A Ward2and Daniel J Sargent1

The Rosoideae is a subfamily of the Rosaceae that contains a number of species of economic importance, including the soft fruit species strawberry (Fragaria 3ananassa), red (Rubus idaeus) and black (Rubus occidentalis) raspberries, blackberries (Rubus spp.) and one of the most economically important cut flower genera, the roses (Rosa spp.). Molecular genetics and genomics resources for the Rosoideae have developed rapidly over the past two decades, beginning with the development and application of a number of molecular marker types including restriction fragment length polymorphisms, amplified fragment length polymorphisms and microsatellites, and culminating in the recent publication of the genome sequence of the woodland strawberry, Fragaria vesca, and the development of high throughput single nucleotide polymorphism (SNP)-genotyping resources for Fragaria, Rosa and Rubus. These tools have been used to identify genes and other functional elements that control traits of economic importance, to study the evolution of plant genome structure within the subfamily, and are beginning to facilitate genomic-assisted breeding through the development and deployment of markers linked to traits such as aspects of fruit quality, disease resistance and the timing of flowering. In this review, we report on the developments that have been made over the last 20 years in the field of molecular genetics and structural genomics within the Rosoideae, comment on how the knowledge gained will improve the efficiency of cultivar

development and discuss how these advances will enhance our understanding of the biological processes determining agronomically important traits in all Rosoideae species.

Horticulture Research (2014) 1, 1; doi:10.1038/hortres.2014.1; published online 22 January 2014

THE ROSACEAE

The Rosaceae family comprises some 90 genera containing approximately 3000 species which include: economically important fruit trees such as cultivated apples (Malus pumila Mill.) and pears (Pyrus spp.); stone fruits including peaches (Prunus persica) and sweet cherries (P. avium); numerous ornamental species, including the roses (Rosa spp.), mountain ash (Sorbus aucuparia) and ninebark (Physocarpus opulifolius); and the soft-fruit species strawberry (Fragaria 3ananassa), raspberry (Rubus idaeus) and blackberry (Rubus spp.), among many others. Several classifications of the family based on morphology have been proposed (e.g., ref. 1), while Schulze-Menz2proposed the categorisation of the family into four subfamilies: Maloideae, Amygdaloideae, Rosoideae and Spiraeoideae based on chromosome number and fruit type. Molecular phylogenetic analyses strongly supported the monophyly of the Rosaceae and demon-strated that chromosome number is a better character for subclassi-fication within the family than fruit morphology.3,4

ROSOIDEAE PHYLOGENETICS

Morgan et al.3 were the first to establish the monophyly of the Rosoideae within the Rosaceae, and the subsequent reclassification of the family by Potter et al.5_{retained the Rosoideae as a subfamily} resulting from the first phylogenetic split within the family. Figure 1 shows a schematic depiction of the phylogeny of the Rosaceae adapted from Potter et al.5diplaying the three main subfamilies Rosoideae, Spiraeoideae and Dryadoideae, and the tribes within each subfamily. According to this molecular classification,5 the Rosoideae subfamily contains a single supertribe, the Rosodae, containing all genera except for Filipendula. Rosodae genera are

contained within three tribes, the Sanguisorbeae, the Potentilleae (containing the Fragariinae subtribe to which the genus Fragaria belongs) and the Colurieae. Rosa and Rubus, which are contained within the Rosodae, are not contained within any tribe. Plants of the Rosoideae are characterized by a base chromosome number of x57. The majority of the plants within the subfamily are perennial herbs and shrubs; however, a small number of annual herbs and perennial tree species exist within the current classification.5

Rosoideae genera contain diverse numbers of species; the genus Fragaria for example contains relatively few species, with just 21 currently recognised and described,6while Rosa is thought to con-tain at least 120 species,7Potentilla up to 500 species8and Rubus some 750.9Species contained within the Rosoideae genera exhibit impressive morphological diversity and exist at numerous ploidy levels, and thus, the classification and phylogenetic determination of species within each genus have been the subject of various phylogenetic analyses, with molecular phylogenies presented for Fragaria,10_Potentilla,8_Rosa11_{and Rubus.}9_{Within these studies, the} evolutionary origins of some important polyploid species in relation to extant diploid progenitors have been determined.

THE ROSOIDEAE AND ITS ECONOMIC IMPORTANCE

The Rosoideae contains species prized for their ornamental value such as Rosa species, those that produce sweet edible aggregate and accessory ‘fruits’ including Rubus idaeus (red raspberry) and Fragaria 3ananassa (cultivated strawberry), highly dispersed wild herbaceous species such as Potentilla reptans and species that have become regarded as invasive pests such as Rosa rubiginosa.12The economic importance of the subfamily is exemplified by three main

1

Research and Innovation Centre, Fondazione Edmund Mach, San Michele all’Adige, Italy and2

Driscoll’s, Watsonville, CA, USA. Correspondence: DJ Sargent (dan.sargent@fmach.it)

genera, Fragaria, Rosa and Rubus, although other genera of more minor economic value exist. Fragaria and Rubus species are valued for their ‘fruits’, which take the form of berries (swollen receptacles that bear the true fruits, the achenes on their surface) in Fragaria, and aggregates of druplets in Rubus, while Rosa is prized for its large, often fragrant and colorful flowers and over 20 000 commer-cial rose cultivars are reported to exist worldwide.13Together, pro-ducts of these three genera are of immense economic significance, which has prompted the need to continually produce improved varieties of both flowers and ‘fruits’ for a market that is constantly increasing its demands in terms of quality and quantity. As a con-sequence of the demand for new varieties, breeding programmes for the genetic improvement of key species have been established worldwide, and in line with almost all other crop plants, a huge investment in the development of molecular tools to assist these programmes, and to answer more fundamental biological ques-tions, has been made over the past 20 years. This review will outline the major advances made in molecular genetics and genomics research in the Rosoideae over the past two decades and highlight the direction this research will take in the coming years in the light of technological advances made in the field of biological sciences.

ROSOIDEAE CYTOLOGY AND ESTIMATES OF GENOME SIZE Cytological studies performed on members of the Rosoideae including Fragaria, Potentilla, Rosa and Rubus have demonstrated

the base chromosome number of the subfamily to be x57, and further works have categorised and described the karyotypes of different species within the genera.14–17 While the base chro-mosome number of members of the Rosoideae is the smallest for any of the plants within the Rosaceae,18polyploidisation events within each of the genera has led to species with diploid chro-mosome counts (2n52x514) through to tetradecaploid (2n514x598) being reported, as well as various aneuploids and interploidy hybrids.19 Fertile interspecific hybrids have been reported within discrete ploidy levels in many of the genera, sug-gesting that within a genus, species are closely related20,21and while intrageneric hybrids between Fragaria and Potentilla22have been produced, viable fertile hybrids were observed only at higher levels of ploidy.

The genomes of diploid Rosoideae species that have been inves-tigated to date were shown to be relatively small, with estimates made using flow cytometry for diploid Rosa species ranging in size between subgenera from 0.78 pg/2C–1.29 pg/2C by Yokoya et al.23 to 1.10 pg/2C–1.36 pg/2C by Rajapakse et al.,7who estimated a genome size in nucleotides of ,600 Mbp/C, while the estimate for Rubus species ranged from 0.58 pg/2C for R. ideaus24 to 0.75 pg/2C for R. sanctus.25The genome size estimate of F. vesca was determined by flow cytometry through comparison with the 125 Mbp/C sequenced genome size of Arabidopsis thaliana (0.34 pg/2C) and was determined to be 164 Mbp/C (and thus pre-sumably in the range of 0.45 pg/2C);26 however, this was later

Figure 1. A schematic representation of the phylogeny of the Rosaceae adapted from Potteret al.,5showing three subfamilies: Rosoideae (red); Spiraeoideae (blue) and Dryadoideae (yellow) and the tribes within each family. The relative size of each triangle represents the relative number of genera contained/analysed in each tribe in the phylogenetic reconstruction by Potteret al.5

adjusted in the light of changes in the size estimates of the Arabidopsis genome27_{to be in the region of 206 Mbp/C. The} gen-ome size of the cultivated octoploid strawberry was also estimated in the same study and determined to be, following adjustment against new estimates of the genome size of A. thaliana, in the region of 703 Mbp, less than four times the estimated genome size of the diploid Fragaria, suggesting extensive loss of chromosomal content following polyploidisation.26 Thus, Rosoideae genomes have been estimated to be among some of the smallest of all angiosperm genomes, with Fragaria having the smallest, followed by Rubus and then Rosa.

MOLECULAR MARKER DEVELOPMENT AND APPLICATION Arbitrary marker systems

Numerous molecular marker systems have been employed in a large number of genetic analyses of Rosoideae species over the past 20 years. These include arbitrary Polymerase Chain Reaction (PCR)-based marker systems, such as amplified fragment length polymorphisms (AFLP), random amplified polymorphic DNA (RAPD) and inter-simple sequence repeats. These marker systems were used in Fragaria, Rosa and Rubus for a range of genetic ana-lyses, including cultivar and sport identification and genetic finger-printing of closely related germplasm;28–30parentage analyses and evaluations of genetic diversity among species;31–34linkage map construction;35–37and population genetics38,39. The inherent lim-itations of arbitrary marker systems in transferability and repro-ducibility between populations, species and laboratories, however, have meant that, as in the vast majority of plant species, more robust, sequence-characterized marker systems such as microsatellites have gained greater favour in genetic analyses in recent years.

Microsatellite markers

Microsatellite development. Microsatellites, or simple sequence repeats (SSRs) are PCR-based, sequence-characterized markers that have become the marker of choice for genetic analysis. Prior to the advent of second-generation sequencing technologies, various protocols for the efficient characterisation of SSRs from enriched genomic libraries of Rosoideae species were reported,40–42along with the characterisation of SSR markers from expressed sequence tag (EST) libraries.43–45_{Subsequently, following the availability of} high-throughput sequencing methodologies and the release of the F. vesca genome sequence,46 _{SSR markers were developed in} abundance for both Fragaria, where more than 4000 SSRs have been characterized from the genome sequence and mapped in both wild and cultivated species,47,48 and Potentilla from which 74 SSR markers were characterised from 1476 sequences identified in 454 genomic sequence data derived from P. pusilla.49

Cultivar identification. In Fragaria, Rosa and Rubus, SSR markers have been successfully employed for cultivar identification. In Fragaria, a set of 10 SSRs in three multiplexes have been reported for fingerprinting cultivated strawberry germplasm,50,51, and more recently, Chambers et al.52used 16 high repeat number SSR mar-kers to discriminate between a collection of 219 cultivated straw-berry varieties. In rose, 24 polymorphic SSR markers were used to characterise over 70 hybrid tea and rootstock varieties,53while just six SSR markers were needed to effectively discriminate between 65 accessions of old garden roses.54_{Likewise in Rubus, 21 SSR markers} were used to discriminate between 148 wild and cultivated black raspberry accessions,55 _{and two fingerprinting sets have been} developed for red raspberry.56,57

Transferability between species. While SSR markers are robust and reliable for genetic analysis within a species, their transferability

between species and genera is more limited than for other marker types. Despite reports of transferability of SSR markers between Rosaceous genera being possible,58,59_{in practice, most of the} mar-kers reported display very low levels of polymorphism and thus there are only a few examples of SSR markers from other Rosaceous genera being employed successfully for genetic analysis in Rosoideae species.7

The rate of transferability and heterozygosity of SSR markers has been investigated within the Rosoideae. Within genera, the trans-ferability of SSR markers is high and markers developed from one species have been shown to be directly applicable to other species. Davis et al.60and Zorilla-Fontanesi et al.61demonstrated up to 90% transferability of polymorphic SSR markers from diploid to octo-ploid strawberry and others47,48,62have employed large numbers of diploid Fragaria SSR markers in the construction of linkage maps of the cultivated strawberry. Likewise in Rubus, SSR markers developed for red raspberry were successfully used to genotype accessions of black raspberry and five other Rubus species by Fernandez Fernandez et al.,56 while Marulanda et al.63 demon-strated the transferability of SSR markers developed in a number of Rubus species to the Andean blackberry, R. glaucus. Similarly, high rates of SSR transferability have been observed in other Rosoideae genera, including Potentilla49_{where 86%–94%} transfer-ability between species was reported.

Lewers et al.43 reported that transferability of SSR markers between the genera was low (31%–19%), while Rousseau-Gueutin et al.64reported transferability of Fragaria EST-SSRs to Potentilla as 75%, while to Rosa, it was just 30%. Koning-Boucoiran et al.65found that just 17% of the Fragaria SSR markers tested transferred to Rosa and just 2% were heterozygous in a rose mapping population. Park et al.,44however, demonstrated higher rates of transferability from Rosa to Fragaria, reporting that 61% of the EST-SSR markers they developed for Rosa were transferred to Fragaria, 47% of which were reported to be polymorphic. These studies highlight the potential for cross-genera application of SSR markers; however, they also demonstrate that the more distantly related the two genera are, the lower the transferability and polymorphism of SSR loci will be. Thus in practice, as SSR development and characterisation has become easier, molecular genetics research has focused on apply-ing SSR markers to species within the genera from which they were developed, and cross-genera studies have mainly utilized other marker systems for the evaluation of synteny between genera within the Rosaceae and the Rosoideae, such as restriction frag-ment length polymorphism (RFLP) and sequence-tagged site mar-kers developed from ESTs.66,67

RFLPs

RFLPs have been used to a limited extent for the molecular char-acterisation of Rosoideae species, including cultivar identification68 and phylogenetic analyses.39 Since RFLP probes are commonly developed from gene-coding sequence, they are often highly con-served between species. Such markers, termed concon-served ortholo-gous set markers, have found enormous utility in comparative mapping studies between plant genera and even families.69,70In the Rosoideae, they have been employed in the development of a linkage map of rose71 and their conserved nature was also exploited, along with PCR-based markers designed from the con-served coding regions of ESTs, in a study of the conservation of synteny between Fragaria and Prunus.66

Single nucleotide polymorphism (SNP) detection and analysis Traditionally, SNPs in the genomes of Rosoideae species were iden-tified through projects that employed Sanger sequencing to sequence EST collections72,73 or through direct sequencing of PCR products amplified from genomic regions of interest.66,74,75 SNP markers were then scored in progenies either by direct

sequencing of PCR products from specific genotypes or segreg-ating progenies66,74,75 or through the utilisation of the cleaved-amplified polymorphic site approach where suitable restriction enzymes were available, to differentially digest alternative alleles at a locus.76,77Such approaches, while effective and reliable, remain extremely low throughput since individual assays can rarely be multiplexed effectively, and the results are most usually visualised through agarose gel electrophoresis. Thus, for the development of large numbers of markers for mapping and large-scale surveys of populations or varieties, SNPs have not traditionally been used routinely.

Since the advent of second-generation sequencing technologies, however, high-throughput methods for SNP discovery and analysis have been developed, which have revolutionised the ability to dis-cover, screen and associate SNPs in progenies and germplasm col-lections. High-throughput deep sequencing of both genomic DNA and mRNA (termed RNA-seq) has been used to identify SNPs in both Fragaria,78Rubus79and Rosa,80following which a number of down-stream analysis methods are available for interrogation and analysis of thousands of SNP markers in a single genotyping assay. Novel techniques have been developed for assaying large numbers of SNPs using the Illumina sequencing platform; Celton et al.78 exploited reduced representation restriction fragment libraries of the FV3FB selective mapping progeny to identify and map large numbers of SNP markers in diploid Fragaria, while Ward et al.79, using the ‘genotyping by sequencing’ (GBS) approach of Elshire et al.81, developed a densely saturated linkage map for a red rasp-berry mapping population. Likewise, using a novel sequence cap-ture technique utilizing RNA baits termed targeted capcap-ture,82 Tennessen et al.83 developed a high density SNP-based linkage map of F. vesca subsp. bracteata composed entirely of segregating SNP markers.

The use of direct sequencing permits the identification and ana-lysis of large numbers of SNPs without a priori knowledge of their genomic position or nature, but the data generated are technically demanding to analyse and interpret reliably and accurately. If SNP data are already available for an organism, however, a number of other genotyping assays have become available and have begun to be exploited recently in Rosoideae species. Kompetitive (sic) allele-specific PCR, which can be used to genotype individual SNPs in moderate numbers (96-1536) of individuals reliably and accurately, has been used to generate segregation data for mapping in tet-raploid rose,65while high-throughput, massively multiplexed gen-otyping array technology, which permits the interrogation of tens of thousands of SNPs simultaneously using microarray technology, has been exploited recently for the development of genotyping tools for wild and cultivated strawberry species.84The development and exploitation of such technologies in the Rosoideae is still in its infancy and there are yet to be full reports of their application in the scientific literature; however, similar technology is currently being applied in related Rosaceous genera such as apple,85peach86and cherry,87and unpublished data suggest that the Istraw90 array for F. 3ananassa is effective at producing mapping data for markers spanning the cultivated strawberry genome.

LINKAGE MAP DEVELOPMENT

Linkage mapping permits the location of genes controlling traits of importance to chromosomes through their association with molecular markers and thus, represents a powerful tool for the positional cloning of major genes, the characterisation of quantitat-ive trait loci (QTL), and the anchoring and ordering of contigs and scaffolds of both physical maps and genome sequence assemblies. With the rapid developments made in molecular marker character-isation and the ease in which they can be used to genotype indivi-duals, genetic linkage maps of Rosoideae species have continually evolved to become increasingly saturated, enabling the genetic

dissection of the genomes of members of the Rosoideae genera and the identification of loci controlling of traits of agronomic importance in Fragaria, Rosa and Rubus.

FRAGARIA

Diploid Fragaria linkage maps

Fragaria species are found in a range of ploidy levels from diploid to decaploid, while the most economically important species, F. 3ananassa, is a complex allo-octoploid. The phylogenetic origins of the octoploid species Fragaria have been investigated and evid-ence that a number of extant diploid species, including F. vesca and F. iinumae, have genomes similar to the diploid progenitors of the modern octoploid species has been presented.10Thus, the applica-tion of molecular markers to genetic mapping studies in Fragaria has permitted the investigation of the structure of both the diploid and octoploid genomes, comparative genomic analyses, the development of saturated maps of the cultivated species and the identification of markers useful for breeding.

Genetic investigations of the genome of the cultivated straw-berry were initially confounded by its complex polyploid nature and thus, initial linkage studies focused on F. vesca a wild diploid closely related to the polyploid strawberry species.10The first link-age map for F. vesca spanning the expected seven chromosomes of the species was reported by Davis and Yu.35 _{The map was} developed from an F2population comprising 80 individuals derived from an intraspecific cross between F. vesca var. Baron Solemacher and the F. vesca accession WC6. The map was composed of a total of 80 markers resolved into seven linkage groups and covering a gen-etic distance of 445 cM. This map included 75 RAPD markers (64 dominant and 11 codominant), a gene-specific marker for the alco-hol dehydrogenase locus, two isoenzyme markers, phosphoglu-cose isomerase (Pgi-2) and shikimate dehydrogenase (Sdh), and morphological markers for the major genes controlling the runner-less (r) and yellow fruit color (c) phenotypes.

Subsequently, a second diploid Fragaria linkage map was reported by Deng and Davis.88 They used two F2 populations derived from a cross between F. vesca subsp. bracteata DN1C and the F. vesca variety Yellow Wonder, and a cross between Yellow Wonder and the F. nubicola accession FRA520 containing 40 indi-viduals each, to map six candidate genes: chalcone synthase, chal-cone isomerase, flavanone 3-hydroxylase, dihydroflavonol 4-reductase, anthocyanidin synthase structural genes and a Del-like regulatory gene. The genes mapped to five of the seven Fragaria linkage groups, identified through comparative mapping of RAPD markers previously mapped by Davis and Yu.35In the study, they showed, through cosegregation, that a mutation in the flavanone 3-hydroxylase gene of the anthocyanin biosynthesis pathway was likely responsible for yellow fruit colour in the variety Yellow Wonder.

Following the development of these initial linkage maps using predominantly arbitrary PCR-based markers, a map characterizing an interspecific mapping progeny was reported by Sargent et al.20. A total of 73 molecular markers (66 SSR, 1 sequence-characterized amplified region (SCAR) and 6 gene-specific markers) and three genes controlling morphological traits were mapped in an F2 popu-lation of 94 individuals (later reduced to 76) obtained from a cross between F. vesca f. semperflorens ‘815’ and F. bucharica ‘601’ (for-merly F. nubicola ‘601’) (FV3FB). The map covered 448 cM and was resolved into the seven linkage groups expected for the genus. A high degree of segregation distortion was observed along the link-age groups, which was suggested to have arisen from the interspe-cific nature of the cross.20This genetic differentiation, however, permitted greater numbers of markers to be mapped compared with previous intraspecific mapping progenies and thus, it was adopted as the international reference mapping progeny for Fragaria.

Successive studies have refined and improved the FV3FB ref-erence map, continually adding markers, including SSRs, gene-spe-cific markers, RFLPs, SNPs and ESTs, and increasing the degree of saturation along the linkage groups.46,61,66,76,78,89–93 The most recent incarnation of the FV3FB map93comprises a total of 411 sequence characterised markers (SSR, RFLP, EST and gene-specific markers) mapped in the full progeny of 76 individuals, and a further 298 markers mapped using a selective mapping strategy using just six seedlings that divided the linkage groups into a total of 46 mapping bins covering the Fragaria genome.91_{The total length} of the current FV3FB linkage map is 442.8 cM across seven linkage groups, comparable to that of the first diploid strawberry map which covered 445 cM35 and is estimated to almost completely cover the diploid Fragaria genome.93Due to the exclusive use of sequence-characterized markers in its construction, the diploid Fragaria reference map was employed to anchor and orientate the genome sequence scaffolds that were derived from the sequen-cing of the F. vesca Hawaii 4 (FvH4) genome by Shulaev et al.46

The release of the FvH4 genome sequence46_{provided an} essen-tial resource for re-sequencing projects aiming to develop SNP-based linkage maps for Fragaria. In order to study male sterility in the gynodioecious diploid strawberry F. vesca subsp. bracteata, par-ental molecular maps of an intraspecific mapping population were developed.83The maps contained a total of 7802 SNP and in-del markers, and following linkage analysis, the seven expected linkage groups were resolved on both maps. The 4338 markers that mapped to the maternal map covered 410 cM, while the paternal map comprised 4305 markers spanning 406 cM. These lengths are comparable with the F. vesca diploid maps previously developed (445 cM in the map of Davis and Yu,35442.8 cM in the map of Sargent et al.93_).

Octoploid Fragaria linkage maps

The cultivated strawberry F. 3ananassa originated from the chance hybridization between the allo-octoploid species F. virginiana and F. chiloensis.94 Several genomic formulas, based on cytological observations, have been proposed for the cultivated strawberry, the most commonly accepted of which is that of Bringhurst,95 who proposed the genomic composition AAA9A9BBB9B9 reflecting the contention that the allo-octoploid Fragaria genomes are com-pletely diploidised and that segregation is comcom-pletely disomic. Initial mapping efforts in the cultivated strawberry suggested that evidence for mixed disomic and polysomic inheritance was observed.96However, the growing availability of numerous codo-minant transferable markers previously mapped to the diploid ref-erence map greatly facilitated the development of well-characterized linkage maps for both F. 3ananassa and F. virginiana47,62,97and novel techniques for studying segregation through microsatellite allele dose and configuration establish-ment98_{have demonstrated that segregation in the allo-octoploid} Fragaria is exclusively disomic and that the genome is fully diploi-dised as suggested by the genome model proposed by Bringhurst.95.

The first linkage maps of the cultivated strawberry were reported by Lerceteau-Ko¨hler et al.96. The maps were constructed from a full-sib F1progeny comprising 133 individuals from a cross between the variety Capitola and the breeding line CF1116 ([Pajaro3 Earlyglow]3Chandler) (CA3CF) and were generated using 789 AFLP markers and two putative genes, alcohol acetyl transferase and dihydro-flavonol 4-reductase. The female and male parental maps contained 235 and 280 markers and were resolved into 43 linkage groups covering 1604 cM and 1496 cM, respectively. Subsequently, the CA3CF map was extended using a larger popu-lation of 213 seedlings and new AFLP, SCAR and SSR markers were added to the existing AFLP framework.99The additional markers extended the maps to include 367 markers covering 2582 cM on

the maternal map and 440 markers covering 2165 cM on the pater-nal map. Integration of the two maps resulted in a fipater-nal consensus map for the progeny spanning 2195 cM across 32 Linkage Group (LG)s. Through comparison of common markers mapped to the diploid Fragaria reference map, linkage groups representing four homoeologous groups were identified for six of the seven diploid LGs, with just three homoeologous groups recovered for LG2. The study highlighted extremely high levels of macrosynteny between the diploid and octoploid maps, suggesting the absence of major chromosomal rearrangements during the evolution of polyploid Fragaria species from their diploid progenitors and validating the use of the FV3FB linkage map as a reference for the genus. The addition of sequence-characterized markers also supported the conclusion that disomy was the predominant, if not the only, mei-otic behaviour exhibited by the F. 3ananassa genome.

While the maps of the CA3CF progeny spanned the majority of the F. 3ananassa genome and were well saturated with markers, the predominant marker type used for the development of the maps was AFLPs. Subsequent maps of octoploid strawberry proge-nies employed larger numbers of transferable markers. In order to study sex determination, Spigler et al.97developed the first SSR-based linkage map of an octoploid strawberry species. A total of 210 SSR markers derived from various genomic sources were mapped in a F. virginiana mapping population raised from a cross between a female maternal line and a hermaphrodite male line. The progeny consisted of 184 individuals and the resultant consensus linkage map had a total length of 2373 cM across 42 linkage group frag-ments, 14 more than expected for a consensus map of the species. An updated map for the progeny was presented by Spigler et al.,100 composed of linkage group fragments associated with 30 linkage groups per parent; however, in their second report, the authors chose to present the female and male linkage maps separately rather than as a consensus map.

Subsequently, two integrated linkage maps of the cultivated strawberry, F. 3ananassa, were reported. The first was developed to investigate the inheritance of resistance to Verticillium dahliae and was derived from a cross between the resistant cultivar Redgauntlet and the susceptible cultivar Hapil.47,101The integrated map had a total length of 2140.3 cM and was developed from a progeny of 174 seedlings. The map, which was almost the same length as the AFLP-based linkage map developed by Rousseau-Gueutin et al.,99_{contained 549 molecular markers (89% of which} were SSR and gene specific markers) and was resolved into the expected 28 LGs for an integrated map. One of the groups, how-ever, was composed of separate female and male maps since no biparental markers for that LG segregated in the progeny. While no data pertaining to wilt resistance were reported in either mapping study, due to the transferable nature of the markers, a comparison with maps developed in previous investigations and of loci on each of the four F. 3ananassa homeologous linkage groups correspond-ing to the seven linkage groups of the diploid reference map was possible. In line with other studies, the authors demonstrated a high degree of colinearity between the diploid and the octoploid Fragaria genomes. Moreover, this work highlighted regions of homozygosity within the F. 3ananassa genome also present in other F. 3ananassa linkage maps, including those of Rousseau-Gueutin et al.99and Zorilla-Fontanesi et al.,62 which the authors suggested were evidence of selection in the genome of the culti-vated strawberry, since such regions of homozygosity were not evident on the linkage map of F. virginiana presented by Spigler et al.100_{The second integrated SSR map reported for F. 3ananassa} was composed of 338 markers, of which 250 were SSRs, and was developed from a mapping population obtained from a cross between two F. 3ananassa lines 232 (4-433Vilanova) and 1393 (Gaviota3Camarosa) (23231393), for the purposes of studying the genetics of fruit quality.62 The total length of the map was 1259.8 cM spanning 37 linkage groups, exceeding the 28 expected

groups for an integrated map of the species; however, all the LGs included a marker present in the reference map (FV3FB) allowing the assignment of each linkage group fragment to one of the seven diploid LGs and permitting further map comparisons between the diploid and octoploid maps to be performed. Later, the resolution of the linkage map was increased through the mapping of addi-tional markers.102 In that study the O-methyltransferase locus, along with other candidate genes, was mapped and a QTL analysis to identify loci controlling the production of volatile compounds was performed. The total length of the integrated map was increased to 1400.1 cM and 363 markers (70% of which were SSRs) were mapped to 39 linkage groups fragments, all but one of which was assigned to one of the four homeology groups assoc-iated with each diploid linkage group.

The most comprehensive linkage map developed for the culti-vated strawberry to date was recently reported by Isobe et al.48In their study, the authors developed an integrated linkage map com-posed exclusively of transferable SSR markers from parental linkage maps of three mapping populations: the F1progeny of the crosses 02-193Sachinoka containing 188 individuals and Kaorino3 Akihime containing 140 individuals, and an F2progeny 0212921 containing 169 individuals derived from the selfing of an unnamed genotype. Constructed from five linkage maps, the integrated con-sensus map produced encompassed a larger amount of diversity than one map could individually and contained a total of 1856 loci distributed throughout 28 linkage groups spanning a total length of 2364.1 cM. This map is of a comparable length to the maps pre-viously reported by Rousseau-Gueutin et al.99 (2195 cM) and Sargent et al.47 (2140.3 cM) and was nearly twice the length of the map developed by Zorilla-Fontanesi et al.102Given the uniform-ity in linkage group lengths of the majoruniform-ity of maps of the cultivated strawberry presented to date, and the high numbers of markers mapped in the study of Isobe et al.,48it is reasonable to assume that the current integrated linkage map covers the majority of the cultivated strawberry genome.

Mapped traits and QTL analysis. Molecular maps are essential for the investigation of the inheritance of important traits and the genes that control them, and thus, are an important precursor for the development of marker assisted selection (MAS) programs. Targeting the genetic elements controlling important agronomic traits like fruit quality, disease resistance or metabolic content, is a crucial step for crop improvement. These traits are, however, usually controlled by QTL, which makes the identification of the genetic determinants accounting for smaller percentages of the genetic variance challenging. Genetic analysis of QTL in polyploid species gives insight into the relationship of how gene copy number influ-ences the trait of interest, and one of the major challenges to gen-etic research in the cultivated strawberry is understanding how homoeologous gene loci impact the genetic control of agronomi-cally-important traits. The sections below describe some of the traits that have been characterized genetically in Fragaria species.

Disease resistance

There are a number of economically significant fungal pathogens which cause severe damage to strawberry crops worldwide. These diseases include Botrytis cinerea (grey mould), those of the genus Phytopthora, including Phytophthora fragariae (red stele) and P. cactorum (crown rot), V. dahliae, and members of the genus Colletotrichum, most notably C. acutatum (blackspot or anthrac-nose). As natural resistance to many of these diseases exists in F. 3ananassa germplasm, attention has been focused on the development of molecular markers to characterize and select for resistance through linkage mapping. An F1population containing 60 individuals obtained from a cross between the F. 3ananassa selection Md683 and the variety Senga Sengana was used in the

first study of marker-trait linkage in the cultivated strawberry.103,104 The trait under investigation was resistance to the soilborne fungus P. fragariae var. fragariae, the cause of the red stele root rot dis-ease.103Seven RAPD markers linked to the Rpf1 gene were iden-tified and one of them was cloned and later converted to a SCAR marker linked in coupling phase to the resistance gene.104Hitherto, however, there have been no reports of the use of this marker in breeding programmes. Indeed alone, it has been reported that the marker is not sufficient for the selection of comprehensive resist-ance to red stele, which to be effective involves the pyramiding of three resistance genes, Rpf1, Rpf2 and Rpf3.105_{Using the map of} Lerceteau-Ko¨hler et al.,96five QTL for resistance to P. cactorum and five for resistance to C. acutatum were characterized and mapped by Denoyes-Rothan et al.106Later two SCAR markers linked to the Rca2 anthracnose resistance gene conferring resistance to C. acu-tatum were developed,107 and subsequently, the markers have been used in a programme of marker-assisted breeding, despite permitting selection for just C. acutatum pathogenicity group 2.105 Recently, markers were identified linked to V. dahliae resistance in ‘Redgauntlet’ using the RG3H mapping population of Sargent et al.47_{. A number of QTL were identified, with the most promising} markers developed from a hydroxyproline rich glycoprotein on LG1, one allele of which was present in the majority of the resistant cultivars screened, and absent from susceptible genotypes (Sˇurbanovski et al., unpublished data), showing promise for the development of an MAS strategy for the selection of novel resistant material.

Flowering habit

Cultivated strawberries are divided, according to their flowering habits, into two primary types: short-day (SD) and day-neutral (DN). SD genotypes require a day length shorter than 14 h or tem-peratures below 156_{C to initiate flowers, while DN plants require}

only moderate temperatures to begin flowering, being insensitive to photoperiod. DN plants are also defined as everbearing; how-ever, not all everbearing plants have the same flowering behaviour as DN types. The first DN cultivars were released in 1979 and all are descended from an accession of F. virginiana subsp. glauca from the Utah mountains, with the DN flowering characteristic introduced by backcross breeding. In favourable conditions, DN cultivars can pro-duce fruit continuously all summer and into the autumn. Many everbearing cultivars have existed for much longer than DN types, but typically, they have a different cropping pattern, with two or three peaks during each growing season.

In order to study the genetics of flowering habit in the cultivated strawberry, a map resolving a single linkage group was developed containing markers linked to the Everbearing (Ev) trait.108 _{In the} study, 199 F1seedlings from a cross between two Japanese octo-ploid varieties Ever Berry and Toyonoka were used to map 5 RAPD markers in the 39.7 cM surrounding the dominant gene (Ev) regu-lating day-neutrality.108This was the first report of DNA markers linked to Ev in strawberry, but as the markers were 11.8 cM and 15.8 cM on either side of the gene, they were not close enough to be useful in breeding selection. Later 127 seedlings obtained from a cross between the DN variety Tribute and the short day Honeoye (T3H) were scored with AFLP primer combinations to identify QTLs associated with the day neutrality habit.109_{The mapping approach} allowed the identification of eight QTL linked to the trait, one of which explained the 36% of the variability, indicating that while day-neutrality is accepted as being controlled by a single dominant gene in cultivated strawberry progenies, the regulation of the trait under different environmental conditions may be polygenic, at least in the T3H cross. More recently, Gaston et al.110scored per-petual flowering as a dominant gene (PF) under Mendelian inher-itance in the CA3CF population and mapped the trait to LG4b-f. When scored as a QTL, the locus was shown to colocalize with a

major dominant QTL that the authors reported also regulated the production of runners (RU), and thus, the locus was denoted FaPFRU. The results of this study have implications for the develop-ment of markers for the selection of these two traits, both of which are of immense importance to commercial strawberry production.

Fruit quality

Fruit quality traits are major targets in breeding programs and as such a better understanding of the genetic basis controlling these traits is a crucial step towards the implementation of MAS for fruit quality. Agronomic, physical and chemical traits have been evalu-ated in different studies to determine their genetic control.62,102,111 In total, 87 unique QTLs were detected for 19 analysed traits in the study of Lerceteau-Ko¨hler et al.,11133 were detected for 14 of the 17 agronomic and quality traits studied in the 23231393 progeny by Zorilla-Fontanesi et al.,62

and 70 QTLs for 48 different volatile com-pounds were detected in the companion study performed by Zorilla-Fontanesi et al.102 _{on the same population. Some of the} considered traits were common between the studies and those such as fruit weight, firmness, soluble-solids content, titratable acid-ity, pH and anthocyanins, mapped to the same LG in the two map-ping populations, and in all three works, a non-random distribution of QTLs was observed, with clustering of QTL observed. Another common feature of the three investigations was the presence of homoeo-QTLs, that is, QTL controlling a particular trait that mapped to orthologous positions on homoeologous linkage groups. In the two progenies studied in the three reports, plant width62, fruit shape, firmness, glucose and malate content, pH,111terpenes lina-lool and terpineol102 were shown to be controlled by homoeo-QTLs, suggesting that more than one homoeologous gene copy regulates the expression of particular quality traits, and raising implications for marker development for MAS.

To date, linkage maps of the cultivated strawberry have been developed by scoring the presence or absence of alleles, i.e., using the alleles as single dose markers. This approach limits the efficiency of QTL mapping as information is discarded where two homeolo-gous loci share a common (multidose) allele. If many of the most economically important traits in the cultivated strawberry are gov-erned by homeo-QTL, a large amount of genetic information and potentially valuable markers would be lost through single-dose allele mapping, since homeo-QTL are likely to share alleles at loci linked to the genes regulating phenotypic expression. A possible solution to this limitation could be the scoring of multidose markers, as has been described by van Dijk et al.,98_{who were able to define map positions} of multidose SSR markers through analysis following capillary elec-trophoresis by calculating allele dose based on their electrophero-gram peak intensities. The methodology proposed to score multidose markers is effective; however, it is labour intensive and is currently not automated, limiting its applicability. Further-more, due to the nature of SSR variability and segregation in F. 3ananassa, reference markers and multiplexes would almost cer-tainly have to be developed de novo for each progeny investigated.

RUBUS

The cultivated red raspberry, R. ideaus subsp. idaeus, has a complex pedigree and in many cases R. idaeus subsp. idaeus cultivars con-tain, to a greater or lesser degree, introgression from R. idaeus subsp. strigosus (the American red raspberry), a fact that has contributed to the high number of molecular markers hetero-zygous in many red raspberry mapping progenies. The distinction between the idaeus and strigosus subspecies is often dismissed by breeders due to the high levels of interfertility between the two species, but the geographic separation has certainly contributed to greater allelic diversity in modern cultivars. In contrast to the high diversity and thus, heterozygosity of R. idaeus, members of R. occi-dentalis (black raspberry) populations tend to be very homozygous

and very limited genetic diversity has been revealed in genetic studies of accessions from throughout the entire geographic range of the species.43,55

Linkage mapping in red raspberry

The first genetic linkage map for red raspberry (R. idaeus L.) was developed by Graham et al.37_{from a full-sib family from a cross} between two cultivars Latham and Glen Moy (L3GM) belonging to different red raspberry subspecies, R. idaeus subsp. strigosus (American red raspberry) and R. idaeus subsp. idaeus (European red raspberry), respectively. The two cultivars used have very dif-ferent morphological characteristics; while Glen Moy bears com-mercially acceptable fruits in terms of flavour, size and colour, on a spine-free plant, it is susceptible to diseases and low-temperature damage, while ‘Latham’ is in contrast extremely hardy, spiny and bears small fruits that are not of a commercially acceptable quality. A total of 30 heterozygous SSR markers, 4 EST-SSR and 206 AFLP markers (240 markers in total) were mapped in the progeny to produce a linkage map covering a total of 789 cM across nine linkage groups. QTL analysis performed on the progeny identified two significant QTL on LG2 accounting for 48%–50% of the pheno-typic variation related to spines on the canes, two QTL on LG8 that explained 33%–79% of the phenotypic variance associated with root sucker spread (diameter), and a single QTL also on linkage group 8 explaining 53% of the variation in root sucker density.

An additional 20 SSR markers were subsequently added to the same linkage map by Graham et al.112, along with additional mar-kers that were scored, but not mapped in the study of Graham et al.37The updated map thus comprised 349 markers and covered a total distance of 669 cM. While some of the linkage groups from the initial study of Graham et al.37were joined following the addition of the new markers, there were still two groups, one from each parent, which could not be associated with each other and therefore, the updated map comprised eight linkage groups. The mapping popu-lation was scored for resistance to cane botrytis (B. cinerea), spur blight (Didymella applanata), cane spot (Elsinoe veneta) and yellow rust (Phragmidium rubi-idaei). The diseases were scored in two growing sites for presence or absence of the disease, as well as on a severity scale for cane botrytis and spur blight.

The gene controlling cane pubescence, gene H, was also mapped in the L3GM mapping population.112The homozygous form of the gene (HH) is rarely found because it is linked with a lethal recessive gene;113however, seedlings carrying a dominant allele for gene H in heterozygous form have been shown to be resistant to cane botry-tis and spur blight,114,115but more susceptible to cane spot, pow-dery mildew (Sphaerotheca macularis) and yellow rust.116–118_Gene H controlling cane pubescence was mapped to LG2 of ‘Glen Moy’ and its association with a QTL for resistance to cane botrytis and spur blight was confirmed.112An additional QTL for resistance to rust, spur blight and botrytis was identified on LG3 of the ‘Latham’ linkage map, along with QTL for resistance to cane spot on LG4 of the ‘Glen Moy’ map and rust on LG5 of the ‘Latham’ map.

A set of 23 EST-SSRs developed from cDNA libraries of roots and flower buds was subsequently mapped to the L3GM map by Woodhead et al.,45_{locating to six of the seven linkage groups of} the map. Fourteen of the newly mapped markers were reported to be associated with QTL for disease resistance, fruit quality, fruit size and developmental stage, although the authors did not elaborate on how variation in these traits was quantified. Subsequently, addi-tional phenotypic data relating to the stages of fruit development from bud break to over ripe fruit, fruit colour, the production of volatile compounds, cane height and cane splitting were scored in the L3GM progeny, and QTL and candidate genes associated variously with these traits were mapped to the seven Rubus linkage groups.119–121In its most recently updated version, 37 gene-specific markers were added to the L3GM linkage map, bringing the total

number of functional markers mapped in the progeny to 97.122_The linkage map now contains a total of 223 molecular markers (57 AFLP and 69 SSR markers, along with the 97 functional markers), covering a total genetic distance of 840.3 cM across the seven expected groups for a consensus linkage map.122

Mapping aphid resistance

A second red raspberry linkage map was developed from a map-ping progeny derived from a cross between the cultivars Malling Jewel and Malling Orion (MJ3MO) containing 94 seedlings. The map was composed of 95 AFLP and 22 SSR markers and covered a total distance of 505 cM over the expected seven linkage groups for a consensus map of the species.90The authors estimated that the MJ3MO genetic linkage map covered approximately 80% of the raspberry genome, with some regions in LG1, which was com-posed mainly of markers segregating in the maternal parent, and further regions of LG3 not completely covered. The map was used to determine the position of a major gene A1involved in the resist-ance to biotype 1 of the aphid Amphorophora idaei, carried by the ‘Malling Orion’ parent, which was located on LG3, 5 cM from the codominant SSR marker Ru103a. Interestingly, the region on LG3 associated with the A1resistance gene was also where QTLs for resistance to cane botrytis, spur blight and rust were located on the linkage map of Graham et al.112In addition to aphid resistance, dwarfism (dw) was also scored in the MJ3MO progeny. Different segregation models have been proposed for this trait, including a two gene model,123 but the segregation data recorded for the MJ3MO progeny (3 : 1) suggested a single gene Mendelian model, in line with that proposed by Jennings.113 However, the gene mapped to LG6 of the MJ3MO map, and was not linked to gene H as suggested by Jennings.113

Mapping Phytopthora root rot resistance

Linkage maps were also produced from a backcross progeny of the cross NY00-34 (Titan 3 Latham) 3 Titan comprising 159 individuals to investigate the inheritance of resistance to root rot (Phytophthora fragariae var. rubi). Linkage maps of the NY00-34 and Titan parents were generated comprising 138 AFLP, 68 RAPD and 20 resistance gene analogue polymorphism markers spanning 440 cM and seven linkage groups on the ‘NY00-34’ map, and 153 AFLPs, 47 RAPDs and 11 resistance gene analogue polymorphisms spanning 370 cM and seven linkage groups on the ‘Titan’ map.124QTL analyses performed on both parental maps for a number of disease criteria identified a region on LG1 of ‘NY 00-34’ and ‘Titan’ accounting for 30%, 61% and 25% and 26%, 33% and 29% of the variance for plant disease index, incidence of petiole lesions and root regeneration, respectively, while a second QTL region located on LG5 of ‘NY 00-34’ was responsible for 28%, 10%, 28% and 15% of the variance of plant disease index, stem lesion size, incidence of petiole lesions and root regeneration, respectively. A second QTL on LG7 of the Titan map was responsible for 15%, 18%, 14% and 16% of the variance for plant disease index, stem lesion size, incidence of petiole lesions and root regeneration score, respectively.

Development of a saturated sequence-characterized reference map for red raspberry

The most comprehensive linkage maps for red raspberry produced to date were reported recently by Ward et al.79Using GBS to gen-erate SNP markers, supplemented with a genome-spanning SSR set, the authors produced highly saturated linkage maps of the parental lines of a mapping progeny produced from the cross Heritage 3 Tulameen (H3T) comprising 71 progeny. The study revealed almost twice the number of heterozygous markers in the Heritage genome than in the Tulameen genome. Linkage maps were composed only of markers segregating in the individual par-ental genotypes and spanned 462.7 cM across seven linkage

groups containing a total of 4521 SNP and 33 SSR markers in 487 genotyping bins on the Heritage linkage map, and 376.6 cM across seven linkage groups containing a total of 2391 SNP and 12 SSR markers in 274 genotyping bins on the Tulameen linkage map (Figure 2).

Due to the nature of the data generated by GBS, the authors proposed a novel imputation strategy that permitted linkage maps to be developed, despite ,30% missing data in each of the parental marker data sets. Almost complete colinearity was observed between the common SSR markers mapped between the H3T linkage map and those previously reported for the L3GM mapping progeny.37,112_{However, while the maps covered approximately the} same physical distance in the two populations, significantly less genetic distance was covered by the H3T linkage maps,79 suggest-ing that recombination rates in the parents of the L3GM map are much higher than those of other Rubus mapping populations. The density of molecular markers mapped in the study permitted the precise mapping of segregation distortion along the linkage groups of the two parental maps and the authors postulated the presence of lethal or detrimental sublethal effects of a number of genetic loci in the R. idaeus genome responsible for the high degree of segrega-tion distorsegrega-tion observed on the H3T linkage maps. Since the SNP segregation data generated was derived from sequencing the pro-geny of the H3T mapping population, the dense saturation of these sequence-characterized markers across the seven R. idaeus linkage groups will be of immense utility for the anchoring and orientation of genome sequence scaffolds produced by the Heritage genome sequencing initiative.

Linkage map development in other Rubus species

Linkage mapping in black raspberry. Linkage mapping investi-gations were recently extended to other members of the Rubus genus. Bushakra et al.125developed a linkage map for black rasp-berry (R. occidentalis) for the purposes of comparison to maps of red raspberry and to other members of the Rosaceae. In their study, the authors developed an interspecific mapping population between an advanced selection of R. occidentalis (96395S1) displaying thorn-less canes and purple fruit, and the red raspberry cultivar Latham which is spiny and bears red fruits (S13L). A linkage map of the S13L progeny was constructed composed of 131 sequence-char-acterized markers; however, the majority of these were mapped in ‘Latham’ due to the inherently low genetic diversity in black rasp-berry.55The 96395S1 linkage map was composed of 29 markers over six linkage groups corresponding to linkage groups LG1–LG6 of the ‘Latham’ linkage map, and spanning a total genetic distance of 306 cM, while the ‘Latham’ map contained 114 markers spanning the expected seven linkage groups and covering a total genetic distance of 561 cM. Subsequently, Bushakra et al.125 used the S13L linkage map to identify compounds relating to the modifica-tion of cyanadin compounds in Rubus. The black raspberry fruits were characterized by two xylose-containing pigments, cyanidin 3-O-sambubioside and cyanidin 3-O-2G-xylosylrutinoside, while the red raspberries contained cyanidin 3-O-sophoroside and cyaniding 3-O-2G-glucosylrutinoside. In total, 27 QTL were identified in the progeny associated with the concentrations of five anthocyanins analysed with ultrahigh performance liquid chromatography that were detected in all 3 years of the study. On the ‘Latham’ parental map, two polyphenolic biosynthetic pathway genes and three tran-scription factor-derived markers were significantly associated with QTL for anthocyanin production. The QTL and their associated mar-kers on LG2 and LG7, one of which encodes a putative component of the MYB/bHLH/WD protein complex involved in the regulation of anthocyanin biosynthetic pathway genes, were previously iden-tified as influencing the concentrations of anthocyanin compounds in raspberry fruits by Kassim et al.126Thus, these loci were con-firmed in the study of Bushakra et al.,125and the authors concluded

that these loci were extremely important for the control of the accumulation of anthocyanns in raspberry fruits.

Linkage mapping in blackberry. As with other Rosoideae genera, Rubus species exist in a number of ploidy levels. Blackberry (Rubus subgenus Rubus Watson) is a species complex and thus, commercial cultivars have a number of species in their pedigree. Tupy is the most important commercial cultivar worldwide but has an uncertain pedigree (Comanche 3 wild Urugauayan blackberry) and an unknown ploidy level. The remaining important cultivars are contained in two groups: the western US developed cultivars (e.g., Marion, Black Diamond, Boysen) that have western and eastern US blackberry species as well as red raspberry (R. idaeus L.) in their pedigree and range in ploidy from 63 to 103 and the cultivars developed from eastern US blackberry species (i.e.. Chester Thornless, Loch Ness, Ouachita, Prime-Ark 45) that are auto-tetra-ploids. The complex genetic background of the species complex has made linkage map construction for these species more chal-lenging than for other polyploid Rosoideae species such as F. 3ananassa due to the complex polysomic inheritance patterns observed in autotetraplooid segregating progenies. Using a full-sib BC1progeny of the cross PrimeJim (Arapaho 3 Ark.830) 3 Arapaho (PJ3AR) containing 188 individuals, a linkage map was developed for tetraploid blackberry to study the inheritance of two single gene traits, primocane fruiting and thornlessness.127Since PrimeJim is duplex for thorny habit (ssSS) and nulliplex for floricane fruiting (ffff) and Arapaho is nulliplex for thorny habit (ssss) and duplex for flor-icane fruiting (ffFF), the progeny was observed to segregate 5 : 1 for both traits in accordance with tetrasomic inheritance in duplex 3 nulliplex crosses. A total of 120 molecular markers were scored in the progeny of which 40 uniparental markers segregated in simplex

(1 : 1), and six segregated in duplex (5 : 1). A further 74 markers segregated bi-parentally; 56 in double simplex (3 : 1), 14 in double duplex (35 : 1) and the remaining 15 in an 11 : 1 ratio indicating a simplex 3 duplex conformation (e.g., Aaaa 3 AAaa or the recip-rocal). Highly distorted markers and those segregating 11 : 1 and 35 : 1 were excluded from the linkage analysis and a linkage map containing eight linkage groups for Arapaho and nine groups for PrimeJim was resolved; however, following comparison with com-mon markers placed on other Rubus genetic maps, LG4 and LG5 in PrimeJim and LG5 in Arapaho were resolved into single linkage groups containing two fragments each.127 _{Evidence for double} reduction was observed at a number of loci, but no genotypes were observed that could only have originated from double reduction. The total length of the Arapaho and PrimeJim linkage maps was 788 cM and 768 cM, respectively. The thornless trait S was mapped to LG4 of the map, while primocane fruiting F was mapped to LG7.127

ROSA

Linkage mapping in diploid rose

Debener and Mattiesch36were the first to present a genetic linkage map for Rosa, composed of AFLP and RAPD markers. The two par-ental linkage maps, produced from an F1population of 60 diploid R. multiflora accessions from the cross 93/1-117 3 93/1-119, were composed of a total of 305 molecular markers spanning the expected seven linkage groups for the species. In addition to the molecular markers, two morphological traits, petal number (Blfo) and petal colour (Blfa), were mapped to linkage groups 3 and 2 of the map, respectively. This linkage map was further extended to include an additional 469 markers comprising SSR and RFLP mar-kers, along with gene-specific sequence characterised markers

Figure 2. The SSR- and SNP-based linkage map of the cultivar H3T mapping population developed by Wardet al.79_{comprising 33 SSR markers}

and 4521 SNP markers in 487 genotyping bins distributed throughout the seven linkage groups of theRubusgenome. Genetic distances are given in centiMorgan, cM.

derived from protein kinase and resistance gene analogue poly-morphism genes.71The data set contained a significant number of biparental markers, which permitted the authors to construct an integrated map of both parents, spanning seven linkage groups and containing a total of 520 molecular markers covering 545 cM and estimated to cover more than 90% of the diploid rose genome. Following the map of the 93/1-117 3 93/1-119 population, Crespel et al.128presented a linkage map of an interspecific cross between a dihaploid rose accession of the tetraploid R. hybrida and the diploid species R. wichuriana which contained 91 progeny. This linkage map, composed of AFLP markers, was used to map two major genes, recurrent blooming (r4) and double corolla (d6), the latter being synonymous with the Blfo gene mapped earlier by Debener and Mattiesch,36along with two QTL for the number of thorns. The linkage map was later extended through the mapping of 64 EST- and genomic-SSR markers by Hibrand-Saint Oyant et al.,129which enabled the maps of the parental genotypes to be associated with one another. In that study, a QTL controlling flower-ing date was also identified. Linde et al.130developed a linkage map of a cross between parental lines differing in their susceptibility to powdery mildew (Podosphaera pannosa) and identified three QTL explaining over 80% of the variance for resistance to mildew race 9 and other QTL for resistance to natural populations of mildew. The progeny also segregated for four traits controlled by major genes, Bflo and Bfla mapped previously,36along with absence of prickles and a striped petal phenotype. The map was composed predomi-nantly of AFLP and RGA markers, along with a modest number of SSR markers and a single SCAR, but the relatively high number (,30%) of biparental markers identified permitted an integrated linkage map of the progeny to be developed.

These three linkage maps, along with a fourth described by Shupert et al.131 derived from the cross R. chinensis cultivar Old Blush 3 (R. wichurana cultivar Basye’s Thornless 3 Old Blush), were used by Spiller et al.132to develop an integrated consensus linkage map for rose. The consensus map contained a total of 597 markers, of which 206 were sequence characterised and 59 were common to all four linkage maps. The consensus map spanned a total map length of 530 cM and provided the means to propose a standar-dised linkage group nomenclature for Rosa. Perhaps most impor-tantly, the consensus map permitted the location of ten phenotypic traits controlled by major genes, QTL for seven quantitative traits and 51 gene-based markers, providing a valuable resource for the development of tools for MAS in rose.

Linkage mapping in tetraploid rose

Despite the existence of many diploid rose species, modern rose cultivars are predominantly tetraploid, derived from around eight diploid and a smaller number of tetraploid progenitor species.13 Diploid rose species are thus of immense value in understanding the genetics of specific traits, which would be desirable to intro-gress into commercial cultivars, and as a tool for unravelling the complex genetics of their tetraploid relations. However, such stud-ies on the diploid are not directly applicable to rose breeding and are of limited value in understanding the inheritance of traits in commercial tetraploid rose genetic background.

Thus, following the development of diploid linkage maps for the genus, a linkage map developed from a tetraploid F2rose progeny was reported by Rajapakse et al.7The progeny studied was derived from a cross between an amphidiploid rose selection 86-7 and a tetraploid cultivar Basye’s Blueberry (86-73BB). The meiotic beha-viour of genotypes of this progeny had previously been investi-gated by Ma et al.,133who observed the multivalent formation of between 15% and 74%, and those authors suggested that the pro-geny exhibited partial tetrasomic inheritance. The linkage map of Rajapakse et al.7was produced from an F2population derived from the self-pollination of seedling 90-69 from the 86-73BB cross and

contained 52 plants. Approximately 70% of markers segregated in simplex in each parent, 20% in duplex, while the remaining 10% displayed other segregation types, including markers that dis-played distorted segregation ratios. While the markers segregating in duplex appeared to display segregation patterns fitting to both 15 : 1 and 35 : 1 ratios, indicating that both disomic and tetrasomic inheritance occurred in the progeny, the population size was not large enough to discriminate between the two inheritance types. Thus, the resultant linkage map was composed exclusively of dom-inant markers segregating in simplex and therefore, separate par-ental maps were recovered, containing 15 linkage groups for the 86-7 map and 14 for the 82-1134 map.

Gar et al.134_{developed a linkage map of a cross between two} tetraploid R.hybrida cultivars Golden Gate and Fragrant Cloud (GG3FC). Assuming tetrasomic inheritance due to the segregation ratios observed in the progeny, they mapped 403 markers, which were variously sequence-characterized RFLP, SSR and SNP (cleaved-amplified polymorphic site) markers (65%) and arbitrary AFLP mar-kers (35%) to seven consensus linkage groups for each parent span-ning 632 cM and 616 cM for the female and male parents, respectively. Each linkage group corresponded to a set of four coupling phase homeologous groups. Due to the high number of sequence-characterized markers mapped in the study, the authors were able to show the homology between the tetraploid map and the diploid consensus map of Spiller et al.132and to determine a high degree of conservation in macrosyntenic genome structure between the Rosa and Fragaria genomes.

Further work investigating the modes of inheritance in tetraploid rose progenies was performed by Koning-Boucoiran et al.65Using a progeny from the cross P540 3 P867 consisting of 184 genotypes, segregation of AFLP, nucleotide-binding site and SSR markers segregating in both simplex and duplex with both uniparental and biparental inheritance was scored. While the hypothesis of complete disomic inheritance in the progeny was rejected, marker segregation data displayed evidence for both disomic and tetraso-mic inheritance, and so the authors proposed the hypothesis that the progeny conferred tetrasomic inheritance with some preferen-tial pairing occurring on certain chromosomes. Evidence for double reduction at some codominant SSR loci was also observed; how-ever, it was based on the assumption that all alleles scored mapped to the same locus, and as with the data of Castro et al.127_for black-berry, the mapping data they presented did not conclusively sup-port this assumption. In total, the expected 28 linkage groups (seven sets of four coupling phase linkage groups) were recovered for the female map and 30 groups were recovered for the male map, but not all of the groups contained SSR markers and so four female and five male groups remained unassigned. Using the map, the authors identified three QTL for prickles on the stem explaining 44.1% of the trait variance, and single QTL for both petal number and powdery mildew resistance explaining 12.7% and 8.5% of the variance, respectively.

GENOME SEQUENCING INITIATIVES

High molecular weight DNA library development and sequencing High molecular weight bacterial artificial chromosome (BAC) and fosmid libraries have been developed for Fragaria135,136 and Rosa,137while in Rubus, a protocol for high molecular weight DNA extraction suitable for BAC library construction was published138 and the use of the subsequently-constructed BAC libraries was reported in the literature,139_{but the characterisation of the BAC} library was not. The 18 432-clone Fragaria BAC library was charac-terized through the development of pools for PCR-based screening and clones containing markers from the diploid Fragaria reference map were identified.135However, the library awaits full exploitation. Additionally, a 33 000-clone fosmid library has been developed from the Fragaria species F. vesca subsp. americana, which was